9 results on '"Wagner, Gregory J."'
Search Results
2. A parallelized three-dimensional cellular automaton model for grain growth during additive manufacturing.
- Author
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Lian, Yanping, Lin, Stephen, Yan, Wentao, Liu, Wing Kam, and Wagner, Gregory J.
- Subjects
CELLULAR automata ,GRAIN growth ,THREE-dimensional printing ,SOLIDIFICATION ,MANUFACTURING processes - Abstract
In this paper, a parallelized 3D cellular automaton computational model is developed to predict grain morphology for solidification of metal during the additive manufacturing process. Solidification phenomena are characterized by highly localized events, such as the nucleation and growth of multiple grains. As a result, parallelization requires careful treatment of load balancing between processors as well as interprocess communication in order to maintain a high parallel efficiency. We give a detailed summary of the formulation of the model, as well as a description of the communication strategies implemented to ensure parallel efficiency. Scaling tests on a representative problem with about half a billion cells demonstrate parallel efficiency of more than 80% on 8 processors and around 50% on 64; loss of efficiency is attributable to load imbalance due to near-surface grain nucleation in this test problem. The model is further demonstrated through an additive manufacturing simulation with resulting grain structures showing reasonable agreement with those observed in experiments. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
3. Data-driven multi-scale multi-physics models to derive process-structure-property relationships for additive manufacturing.
- Author
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Yan, Wentao, Lin, Stephen, Kafka, Orion L., Lian, Yanping, Yu, Cheng, Liu, Zeliang, Yan, Jinhui, Wolff, Sarah, Wu, Hao, Ndip-Agbor, Ebot, Mozaffar, Mojtaba, Ehmann, Kornel, Cao, Jian, Wagner, Gregory J., and Liu, Wing Kam
- Subjects
THREE-dimensional printing ,DATA mining ,ROAD maps ,ENGINEERING design ,MANUFACTURING processes - Abstract
Additive manufacturing (AM) possesses appealing potential for manipulating material compositions, structures and properties in end-use products with arbitrary shapes without the need for specialized tooling. Since the physical process is difficult to experimentally measure, numerical modeling is a powerful tool to understand the underlying physical mechanisms. This paper presents our latest work in this regard based on comprehensive material modeling of process-structure-property relationships for AM materials. The numerous influencing factors that emerge from the AM process motivate the need for novel rapid design and optimization approaches. For this, we propose data-mining as an effective solution. Such methods—used in the process-structure, structure-properties and the design phase that connects them—would allow for a design loop for AM processing and materials. We hope this article will provide a road map to enable AM fundamental understanding for the monitoring and advanced diagnostics of AM processing. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
4. Data-Driven Microstructure and Microhardness Design in Additive Manufacturing Using a Self-Organizing Map.
- Author
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Zhengtao Gan, Hengyang Li, Wolff, Sarah J., Bennett, Jennifer L., Hyatt, Gregory, Wagner, Gregory J., Cao, Jian, and Wing Kam Liu
- Subjects
MICROHARDNESS ,THREE-dimensional printing ,SELF-organizing maps - Published
- 2019
- Full Text
- View/download PDF
5. An integrated process–structure–property modeling framework for additive manufacturing.
- Author
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Yan, Wentao, Lian, Yanping, Yu, Cheng, Kafka, Orion L., Liu, Zeliang, Liu, Wing Kam, and Wagner, Gregory J.
- Subjects
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THREE-dimensional printing , *GRAIN growth , *MICROSTRUCTURE , *FATIGUE crack growth , *ELECTRON beam furnaces - Abstract
One goal of modeling for metal Additive Manufacturing (AM) is to predict the resultant mechanical properties from given manufacturing process parameters and intrinsic material properties, thereby reducing uncertainty in the material built. This can dramatically reduce the time and cost for the development of new products using AM. We have realized the seamless linking of models for the manufacturing process, material structure formation, and mechanical response through an integrated multi-physics modeling framework. The sequentially coupled modeling framework relies on the concept that the results from each model used in the framework are contained in space-filling volume elements using a prescribed structure. This framework is implemented to show a prediction of the decrease in fatigue life caused by insufficient fusion resulting from low laser power relative to the hatch spacing. In this demonstration, powder spreading and thermal-fluid flow models are used to predict the thermal history and void formation in a multilayer, multi-track build with different processing conditions. The results of these predictions are passed to a cellular automaton-based prediction of grain structure. Finally, the predicted grain and void structure is passed to a reduced-order micromechanics-based model to predict mechanical properties and fatigue life arising from the different processing conditions used in the process model. The simulation results from this combination of models demonstrate qualitative agreement with experimental observations from literature, showing the appealing potential of an integrated framework. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
6. Meso-scale modeling of multiple-layer fabrication process in Selective Electron Beam Melting: Inter-layer/track voids formation.
- Author
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Yan, Wentao, Qian, Ya, Ge, Wenjun, Lin, Stephen, Liu, Wing Kam, Lin, Feng, and Wagner, Gregory J.
- Subjects
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ELECTRON beam furnaces , *THREE-dimensional printing , *DISCRETE element method , *COMPUTATIONAL fluid dynamics , *HEAT transfer - Abstract
Selective Electron Beam Melting (SEBM) is a promising powder-based metallic Additive Manufacturing (AM) technology. However, most powder-scale modeling efforts are limited to single track process, while it is also difficult to experimentally observe the interaction between tracks and layers. In this study, we develop an integrated modeling framework to investigate the SEBM process of multiple tracks and multiple layers. This approach consists of a Discrete Element model of powder spreading and a Computational Fluid Dynamics (CFD) model of powder melting. These two models exchange 3D geometrical data as a cycle to reproduce the manufacturing process of multiple tracks along various scan paths in multiple powder layers. This integrated modeling approach enables further understanding of how current tracks and layers interact with previous ones leading to inter-track/layer voids. It also incorporates more influential factors, particularly the layer-wise scan strategy. The inter-layer/track voids due to the lack of fusion are systematically discussed in light of our simulation results which qualitatively agree with experimental observations in literature. [ABSTRACT FROM AUTHOR]
- Published
- 2018
- Full Text
- View/download PDF
7. Multi-physics modeling of single/multiple-track defect mechanisms in electron beam selective melting.
- Author
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Yan, Wentao, Ge, Wenjun, Qian, Ya, Lin, Stephen, Zhou, Bin, Liu, Wing Kam, Lin, Feng, and Wagner, Gregory J.
- Subjects
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ELECTRON beams , *THREE-dimensional printing , *SURFACE roughness , *VOIDS (Crystallography) , *PRODUCT quality - Abstract
Metallic powder bed-based additive manufacturing technologies have many promising attributes. The single track acts as one fundamental building unit, which largely influences the final product quality such as the surface roughness and dimensional accuracy. A high-fidelity powder-scale model is developed to predict the detailed formation processes of single/multiple-track defects, including the balling effect, single track nonuniformity and inter-track voids. These processes are difficult to observe in experiments; previous studies have proposed different or even conflicting explanations. Our study clarifies the underlying formation mechanisms, reveals the influence of key factors, and guides the improvement of fabrication quality of single tracks. Additionally, the manufacturing processes of multiple tracks along S/Z-shaped scan paths with various hatching distance are simulated to further understand the defects in complex structures. The simulations demonstrate that the hatching distance should be no larger than the width of the remelted region within the substrate rather than the width of the melted region within the powder layer. Thus, single track simulations can provide valuable insight for complex structures. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
8. A framework to link localized cooling and properties of directed energy deposition (DED)-processed Ti-6Al-4V.
- Author
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Wolff, Sarah J., Lin, Stephen, Faierson, Eric J., Liu, Wing Kam, Wagner, Gregory J., and Cao, Jian
- Subjects
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TITANIUM alloys , *THREE-dimensional printing , *MICROSTRUCTURE , *MECHANICAL behavior of materials , *WELD thermal simulators - Abstract
Additive manufacturing (AM) of titanium alloys is a rapidly growing field due to an increase in design flexibility of parts. However, AM parts are highly anisotropic in material microstructure and mechanical behavior due to the change of the local processing conditions in the build-up process. This study follows a link chain model to investigate the relationships between process parameters, cooling rate, porosity and mechanical behavior. The aim of this work is to present a framework that is inspired by the three-link chain model. The framework combines theoretical, computational and experimental approaches. We demonstrate this by using an in-house thermal simulator to link predicted cooling rates with micrographs describing experimental shape descriptors to develop a relationship between solidification cooling rate and porosity geometry. Finally, representative volume elements from predicted porosity maps allow for a prediction of mechanical properties at localized areas. The capability of being able to predict mechanical behavior of titanium alloys is demonstrated for the directed energy deposition process. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
9. A cellular automaton finite volume method for microstructure evolution during additive manufacturing.
- Author
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Lian, Yanping, Gan, Zhengtao, Yu, Cheng, Kats, Dmitriy, Liu, Wing Kam, and Wagner, Gregory J.
- Subjects
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CELLULAR automata , *THREE-dimensional printing , *HEAT convection , *MICROSTRUCTURE , *EPITAXY , *FINITE volume method - Abstract
Abstract Additive manufacturing (AM) processes produce unique microstructures compared with other manufacturing processes because of the large thermal gradient, high solidification rate and other local temperature variations caused by the repeated heating and melting. However, the effect of these thermal profiles on the microstructure is not thoroughly understood. In this work, a 3D cellular automaton method is coupled to a finite volume method to predict the grain structure of an alloy, e.g. Inconel 718, fabricated by AM. The heat convection due to thermocapillary flow inside the melt pool is resolved by the finite volume method for a real and accurate temperature field, while an enriched grain nucleation scheme is implemented to capture epitaxial grain growth following the mechanism identified from experiments. Simulated microstructure results are shown to be in qualitative agreement with experimental result and the effects of the process parameters on both thermal characteristics and the grain structure are identified. The 3D cellular automaton finite volume method results establish our approach as a powerful technique to model grain evolution for AM and to address the process-structure-property relationship. Graphical Abstract Unlabelled Image Highlights • A 3D cellular automata finite volume method for additive manufacturing is presented, including an enriched nucleation model • The grain structure in the Directed Energy Deposition of IN718 alloy is simulated by the proposed method • The effects of the processing parameters on the resulting grain structure of IN718 alloy are elaborated via the simulation • Sandwich- and zig-zag patterns of grain structure observed in experiments are captured and explained by the proposed model [ABSTRACT FROM AUTHOR]
- Published
- 2019
- Full Text
- View/download PDF
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